Ice maker with specific seal and household refrigeration apparatus

ABSTRACT

An ice maker includes a housing having a wall element. The wall element includes a first wall plate and a second wall plate. A seal is disposed on the housing and seals the housing to an interior container of a household refrigeration apparatus. The seal includes a hollow tube and is disposed as a 3-dimensionally bent and elongated seal. A household refrigeration apparatus having an ice maker is also provided.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation-In-Part of U.S. patent application Ser. Nos. 16/203,005, 16/203,026, 16/203,012 and 16/202,993, all filed on Nov. 28, 2018; the prior applications are herewith incorporated by reference in their entirety.

BACKGROUND OF THE INVENTION Field of the Invention

An aspect of the invention relates to an ice maker including walls. A further aspect of the invention relates to a household refrigeration apparatus including an ice maker.

Household refrigeration apparatuses are known in diverse configurations. In that context, it is also known that an interior container bounds a receiving space for a household refrigeration apparatus. The receiving space is usually a refrigerating compartment. A partial area is occupied by an ice maker in that receiving space. Therefore, it is known that the ice maker is separated from the remaining volume of the refrigerating compartment. In that context, it is provided that a housing area of the housing of the ice maker is formed by a separate wall element, which is attached to inner sides of walls of the interior container in the interior of the receiving space of the interior container.

Thus, it is for example known from U.S. Patent Application Publication No. 2013/0263620 A1 to provide such an ice maker in the left upper corner area in the refrigerating compartment as seen in a front-side view of the household refrigeration apparatus. Through the use of the ice maker, ice form elements, for example ice cubes or crushed ice, can be produced from supplied water. Those ice form elements can be output through an output unit formed at a door of the household refrigeration apparatus.

In the known construction of the household refrigeration apparatus, the separate wall element, which is a constituent part of the housing of the ice maker, is attached to walls of the interior container by multiple screw connections. It is required therein that the wall element is additionally retained by an assembler himself or herself upon assembly in order to be able to generate the screw connections. That is expensive and can also result in incorrect positions of the wall element. Thereby, the accurate position of the wall element at the interior container cannot be satisfied, whereby impairments in the thermal insulation at the interfaces between the wall elements and the inner side of the walls of the interior container optionally also arise.

A further disadvantage of the known construction is to be regarded in that the wall element is formed with a circumferential frame in the front-side area, which is integrally configured. A bracket, which joins to plate elements of the wall element, is formed integrally with those plate elements. Thereby, the integral wall element is very complexly configured in its shape. Therefore, it is also difficult to clean, which optionally results in hygienic impairments of the ice maker.

A further disadvantage of the known household refrigeration apparatus is to be regarded in that condensation water optionally occurring in the housing cannot be transported away. Thereby too, hygienic impairments can occur.

Further an ice maker in a cooling compartment is difficult to be disposed in a thermally isolated manner.

SUMMARY OF THE INVENTION

It is accordingly an object of the invention to provide an ice maker with a specific seal and a household refrigeration apparatus, which overcome the hereinafore-mentioned disadvantages of the heretofore-known ice makers and household refrigeration apparatuses of this general type and which have an improved thermally isolated configuration in the household refrigeration apparatus.

With the foregoing and other objects in view there is provided, in accordance with the invention, an ice maker, comprising:

-   -   a housing including a wall element,     -   the wall element having a first wall plate and a second wall         plate, and     -   a seal disposed on the housing and sealing the housing from an         interior container of a household refrigeration apparatus,     -   the seal including a hollow tube and being disposed as a         3-dimensionally bent and elongated seal.

With the objects of the invention in view, there is also provided a household refrigeration apparatus, comprising:

-   -   an ice maker including a housing,     -   the housing including a wall element,     -   the wall element having a first wall plate and a second wall         plate, and     -   a seal disposed on the housing and sealing the housing from an         interior container of the household refrigeration apparatus,     -   the seal including a hollow tube and being disposed as a         3-dimensionally bent and elongated seal; and     -   the housing being disposed on the interior container.

Other features which are considered as characteristic for the invention are set forth in the appended claims. Further features of the invention are apparent from the claims, the figures and the description of figures. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of figures and/or shown in the figures alone are usable not only in the respectively specified combination, but also in other combinations without departing from the scope of the invention. Thus, implementations are also to be considered as encompassed and disclosed by the invention, which are not explicitly shown in the figures and explained, but arise from and can be generated by separated feature combinations from the explained implementations. Implementations and feature combinations are also to be considered as disclosed, which thus do not include all of the features of an originally formulated independent claim. Moreover, implementations and feature combinations are to be considered as disclosed, in particular by the implementations set out above, which extend beyond or deviate from the feature combinations set out in the relations of the claims.

Although the invention is illustrated and described herein as embodied in an ice maker with a specific seal and a household refrigeration apparatus, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.

The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1 is a simplified, diagrammatic, perspective representation of an embodiment of a household refrigeration apparatus according to the invention;

FIG. 2 is a perspective representation of an embodiment of an interior container of the household refrigeration apparatus;

FIG. 3 is an enlarged partial representation of the household refrigeration apparatus according to FIG. 1;

FIG. 4 is a perspective view of an enlarged representation of a partial area of a housing of an ice maker of the household refrigeration apparatus with an disposed seal;

FIG. 5 is a partial representation of FIG. 4 in a perspective different from FIG. 4;

FIG. 6 is a representation according to FIG. 5, in which a partial area is additionally shown in a horizontal sectional representation;

FIG. 7 is a perspective representation of an embodiment of a separate positioning bracket, which is a constituent of a wall unit of the housing of the ice maker;

FIG. 8 is a representation of the positioning bracket in a perspective different from FIG. 7;

FIG. 9 is a vertical sectional representation of the configuration in FIG. 4, wherein only a partial area thereof is shown in FIG. 9;

FIG. 10 is an enlarged representation of a partial area of FIG. 9;

FIG. 11 is a perspective sectional representation of the household refrigeration apparatus in the area of the ice maker, in which the components according to FIG. 10 are also disposed;

FIG. 12 is a perspective horizontal sectional representation of a partial area of the housing of the ice maker at a location different from FIG. 11;

FIG. 13 is a perspective representation of an embodiment of a wall unit of a housing of an ice maker according to an embodiment different than FIG. 4;

FIG. 14 is a perspective representation of a further embodiment of a housing of an ice maker of the household refrigeration apparatus;

FIG. 15 is a vertical sectional representation through this embodiment according to FIG. 14;

FIG. 16 is an enlarged representation of a partial area of FIG. 15;

FIG. 17 is a representation of a partial area of a rear wall of the interior container with a drain gutter integrated therein for draining of condensation water from the housing of the ice maker;

FIG. 18 is a perspective representation of an upper area of the interior container, wherein a rear wall with the integrated drain gutter is represented there in a rear view;

FIG. 19 is a transparent side view of a further embodiment of an interior container of the household refrigeration apparatus;

FIG. 20 is an enlarged representation of a partial area of the interior container according to FIG. 19;

FIG. 21 is a vertical sectional representation of an upper area of the interior container with a wall unit of a housing of an ice maker of the household refrigeration apparatus disposed thereon;

FIG. 22 is an enlarged representation of a partial area of FIG. 21;

FIG. 23 is a vertical sectional representation corresponding to FIG. 22 at a location different from FIG. 22;

FIG. 24 is a further perspective view of an enlarged representation of a partial area of a housing of an ice maker of the household refrigeration apparatus with an disposed seal as shown in FIG. 4;

FIG. 25 is a perspective view of the 3-dimensionally bent and elongated seal as disposed in FIG. 24;

FIG. 26 is a perspective view showing the seal shown in FIG. 25 in an unbent state; and

FIG. 27 is a perspective view an enlarged end part of the seal in FIG. 26 with an added holder.

DETAILED DESCRIPTION OF THE INVENTION

Initially, it is noted that the indications “top,” “bottom,” “front,” “rear,” “horizontal,” “vertical,” “depth direction,” “width direction,” “height direction,” etc., specify the positions and orientations given in intended use and intended configuration of the apparatus.

Referring now in detail to the figures of the drawings, in which identical or functionally identical elements are provided with the same reference characters, and first, particularly, to FIG. 1 thereof, there is seen a simplified representation of a household refrigeration apparatus 1 which is provided for storing and preserving food. The household refrigeration apparatus 1 includes a housing 2. The housing 2 includes an exterior housing 3. Moreover, the household refrigeration apparatus 1 includes an interior container 4 separate from the exterior housing 3. The interior container 4 is received in the exterior housing 3. A thermally insulating material such as for example insulating foam and/or a vacuum insulating panel is disposed in a clearance 5 between the exterior housing 3 and the interior container 4. The interior container 4 is an inner liner.

In this embodiment, walls of the interior container 4 bound a receiving space 6 which is provided for receiving food. In this case, the receiving space 6 is in particular formed as a refrigerating compartment.

A front side of the interior container 4 includes a loading opening, through which food can be taken into or be removed from the receiving space 6. In this embodiment, the receiving space 6 is closable by two separate doors 7 and 8. The two doors 7 and 8 are pivotably disposed at the housing 2. The two doors 7 and 8 are disposed at the same height position as viewed in height direction (y-direction) of the household refrigeration apparatus 1. In width direction (x-direction) of the household refrigeration apparatus 1, they are disposed next to each other in such a way that they collectively close the receiving space 6 on the front side in the closed state. In particular, these two doors 7 and 8 are disposed in a common plane in the closed state, which is spanned by the height direction and the width direction.

In FIG. 1, the door 7 on the left side, as seen in a front-side view, is illustrated opened and the door 8 on the right side is illustrated closed.

The household refrigeration apparatus 1 includes at least one further receiving space 9 for food. This further receiving space 9 is separated from the first receiving space 6. The further receiving space 9 can for example be a freezing compartment or a keep-fresh compartment or a further refrigerating compartment. As viewed in the height direction, this further receiving space 9 is formed below the first receiving space 6. The further receiving space 9 is in particular bounded by further walls of an interior container, which can also be the interior container 4. Preferably, it is provided that the further receiving space 9 is bounded by a further door 10, which is shown in the closed state in FIG. 1. Preferably, it is provided that this door 10 is formed as a front plate of a drawer linearly retractable and extendable in the depth direction (z-direction) of the household refrigeration apparatus 1.

It can be provided that the household refrigeration apparatus 1 includes multiple, separate further receiving spaces 9, and further such explained drawers are preferably formed in this context. They can be adjoined to the further receiving space 9 towards the bottom as viewed in height direction. They are in particular also formed within the housing 2.

Further, the door 10, in particular this front plate, is disposed in the same plane as the doors 7 and 8 in the closed state of the doors 7, 8 and 10. In particular, the doors 7, 8 and 10 are front-side vision components of the household refrigeration apparatus 1. In particular, they are also, if they are closed, disposed without an overlap with each other.

Moreover, the household refrigeration apparatus 1 includes an ice maker 11. The ice maker 11 occupies a partial area of the volume of the receiving space 6 and is thermally insulated from the remaining volume of the receiving space 6. The ice maker 11 is formed to produce ice from water, which is supplied to the household refrigeration apparatus 1 through an external water supply line. In this context, ice form elements such as ice cubes or crushed ice can be produced.

Further, the ice maker 11 is a constituent part of a dispenser unit 12 of the household refrigeration apparatus 1. In this advantageous implementation, the dispenser unit 12 includes an output unit 13 in addition to the ice maker 11. This output unit 13 can preferably be formed at a door 7, 8. In the shown embodiment, the output unit 13 is disposed at the door 7. This is in particular advantageous because the ice maker 11 is disposed in the left upper corner area of the total volume of the receiving space 6 as seen in the front-side view of the household refrigeration apparatus 1. Short paths for outputting produced ice form elements are achieved by this local positioning. The output unit 13 is fixedly installed at the door 7. Moreover, the output unit 13 is separated from the ice maker 11 and also decoupled from it in this context. In the closed state of the door 7, ice form elements produced by the ice maker 11 can travel into the output unit 13 and be output through a front side 14 of the door 7. Therefore, it is provided that a recess is formed on the front side 14, which faces away from the receiving space 6 in the closed state of the door 7. A vessel can be placed in this recess to be able to collect the output ice form elements.

In particular, the dispenser unit 12 can also be formed for outputting liquid such as water or other drinks in addition to the output of ice form elements.

In FIG. 2, an embodiment of the interior container 4 is shown in a perspective representation. The interior container 4 is preferably integrally produced from plastic, for example by deep-drawing. Injection molding can also be provided.

The interior container 4 includes multiple walls, which bound the receiving space 6. For example, the interior container 4 is formed with a first vertical side wall, which is a first wall 15 in the example, an opposing second vertical side wall 16, a rear wall 17, which is a third wall in the example, a bottom wall 18 and a ceiling wall, which is a second wall 19 in the example.

The first vertical side wall for example represents a first wall 15 of the interior container 4. In one embodiment, the ceiling wall represents a second wall 19 of the interior container 4, which is disposed angled, in particular at an angle of 90°, to the first wall 15.

The ice maker 11 includes a housing 20 (FIG. 1). A receiving space 21 of this ice maker 11 is bounded by the housing 20. The housing 20 includes a wall area 22 (FIG. 2) of the first wall 15 as a constituent part. This wall area 22 is an upper wall area in the configuration according to FIG. 1 and FIG. 2. Moreover, a further constituent part of the housing 20 of the ice maker 11 is formed by a wall area 23 of the second wall 19.

Moreover, the receiving space 21 is bounded by a further wall area 24. This further wall area 24 is an integral constituent of the rear wall 17 of the interior container 4. The wall areas 22, 23 and 24 directly adjoin each other.

Moreover, the housing 20 includes a wall unit 25 (FIG. 1), which is a component separate from the interior container 4. This wall unit 25 is a further constituent part of the housing 20 and bounds the receiving space 21 of the housing 20 in addition to the wall areas 22, 23 and 24.

In FIG. 3, a perspective representation of a partial area of the household refrigeration apparatus 1 is shown. In this case, the housing 20 of the ice maker 11 is in particular shown. The wall unit 25 is shown, which is already represented herein in the assembled state at the interior container 4, in particular in the receiving space 6.

In the illustrated embodiment, the wall unit 25 includes a wall element 26. The wall element 26 is formed with an L-shape in a vertical section (sectional plane spanned by the height direction and the width direction). Therefore, the wall element 26 includes a first wall plate 27. In this case, the first wall plate 27 is oriented in the horizontal direction. Moreover, the wall element 26 includes a vertical wall plate. This vertical wall plate is a second wall plate 28 of the wall element 26. The wall plates 27 and 28 are in particular oriented at an angle of 90° to each other. They extend in the depth direction of the household refrigeration apparatus 1 in their plate shape or in their area shape.

The wall element 26 is formed as a thermal insulating body. This means that the wall element is formed of an outer wall element 29 (FIG. 6) and an inner wall element 30 (FIG. 6). A thermally insulating material 31 (FIG. 16) is formed in a clearance between the outer wall element 29 and the inner wall element 30.

Moreover, the wall unit 25 includes a positioning bracket 32 (FIG. 3). The positioning bracket 32 is in particular integrally formed, for example of plastic. Preferably, the positioning bracket 32 is non-rectilinearly formed. The positioning bracket 32 is preferably formed as an angular part, in particular with an L-shape.

In the embodiment shown in FIG. 3, it is provided that the positioning bracket 32 is a component separate from the wall element 26, but is connected to the wall element 26. In this case a non-destructively detachable connection is in particular provided. Due to such a configuration, on the one hand simpler production of the individual components of the wall unit 25 is allowed. Thereby, on the other hand disassembly is reversibly allowed and the individual parts can for example be better cleaned individually.

As is apparent in FIG. 3, the positioning bracket 32 is disposed on a front area 33 as viewed in the depth direction of the housing 20, which is also the depth direction of the household refrigeration apparatus 1. In particular, the positioning bracket 32 is disposed at the front end of the housing 20. The positioning bracket 32 includes a first bracket leg 34, which is in this case a vertical bracket leg. Moreover, the positioning bracket 32 includes a horizontal bracket leg 35, which is in this case a second bracket leg. As is apparent in FIG. 3, the first bracket leg 34 adjoins the wall element 26 with its free end, in particular it adjoins the first wall plate 27. There, it is non-destructively detachably fixed.

The second bracket leg 35 adjoins the second wall plate 28 with its free end and is there in particular non-destructively detachably fixed.

In this context, the positioning bracket 32 includes a first end 36, which is non-destructively detachably connected to the first wall plate 27. The positioning bracket 32 includes a second end 37, which is non-destructively detachably connected to the second wall plate 28.

Further, the wall element 26 includes a front edge 38. This front edge 38 can be formed by a front flange. In this context, the front flange represents a front-side end part. The front edge 38 can be formed integrally with the interior part 30.

A circumferentially closed frame is formed by the front edge 38 and the positioning bracket 32. Thereby, a front-side opening of the housing 20 is also bounded.

Further, the positioning bracket 32 includes at least one stiffening rib 39. This first stiffening rib 39 is formed on an inner side of the positioning bracket 32. Preferably, it is formed angled, in particular L-shaped.

A stiffening of the wall element 27 in particular in the front area 33 is also allowed by the positioning bracket 32. In particular, an additional separate assembly part is also provided by the positioning bracket 32, by which the wall unit 25 can be disposed at the interior container 4 in improved manner.

In FIG. 4, an embodiment of the wall unit 25 is shown in a perspective representation.

In this example, the positioning bracket 32 includes a plate area 40 at the second bracket leg 34. The plate area 40 extends across the length of the second bracket leg 35 in certain areas, wherein this is viewed in the width direction of the household refrigeration apparatus 1. The plate area 40 is bounded by a bounding wall 41 in such a way that a trough area arises in this case. In this case, the bounding wall 41 is in particular also formed for reinforcement or stiffening. The bounding wall 41 is formed uninterrupted continuously up to the end 36 of the first bracket leg 34.

Moreover, it is also provided in FIG. 4 that a further stiffening rib 42 is formed at the front-side edge of the positioning bracket 32. This stiffening rib 42 too, which extends outwards from an outer side 43 of the positioning bracket 32 in a raised manner, is formed uninterrupted. This further stiffening rib 42 extends from the second end 37 of the positioning bracket 32 up to the first end 36. The stiffening rib 42 extends in the direction of a longitudinal axis oriented along the angled shape of the positioning bracket 32.

Moreover, the positioning bracket 32 includes a further stiffening rib 44. This stiffening rib 44 is formed offset rearward relative to the stiffening rib 42 as viewed in the depth direction and in particular it is oriented parallel thereto. It is also formed uninterrupted. A receiving groove 45, which is formed between these two stiffening ribs 42 and 44, is provided for receiving a seal.

As is moreover apparent in FIG. 4, the first bracket leg 34 includes a hole or an aperture 46. An engagement area 47 of a coupling flap 48 (FIG. 5) engages with this aperture 46. The coupling flap 48 is formed integrally with the first wall plate 27. In particular, this coupling flap 48 is formed integrally with the interior cladding or the integrally formed inner wall element 30 of the wall element 26. Due to this configuration, locking between the positioning bracket 32 and the wall element 26 is also formed. Thus, a locking device between the wall element 26 and the positioning bracket 32 is formed at this first end 36 of the positioning bracket 32. In particular, the coupling flap 48 is formed elastically resilient in such a way that the coupling flap 48 is slightly deformed upon attaching the positioning bracket 32 and then the engagement area 47 snaps or locks in the aperture 46.

As is moreover apparent in FIG. 4, the wall plate 27 includes a web 49 at the end facing away from the second wall plate 28. This web 49 advantageously extends uninterrupted across the entire length of the first wall plate 27, as viewed in the depth direction.

As is apparent in FIG. 4, in which the positioning bracket 32 is shown in its assembled final state with the wall element 26, the first end 36 of the positioning bracket 32 rests on this web 49 from above.

As is moreover apparent in FIG. 4, it is provided in an advantageous implementation that the wall unit 25 includes at least one positioning element. In particular, this positioning element is formed integrally with the wall unit 25. In particular, this positioning element is formed as a plug pin 50. This plug pin 50 laterally protrudes away from the web 49 in width direction. This plug pin 50 is formed to be plugged into a receptacle 51 (FIG. 2), which is formed on the inner side of the first wall 15 of the interior container 4. A pre-assembly position of the wall unit 25 at the interior container 4 is then advantageously allowed by this positioning element.

Additionally or instead, it can be provided that the positioning bracket 32 also includes a positioning element. In particular, this positioning element is formed as a plug pin 52 (FIG. 4) in this case too. In the illustrated embodiment, it is preferably formed in the horizontal second bracket leg 35. In particular, this positioning element is formed in the form of the exemplary plug pin 52 in the plate area 40 and extends upwards from a top side of the plate area 40 in height direction.

The positioning element formed as the plug pin 52 is also formed integrally with the positioning bracket 32.

Further, it is provided that the second bracket leg 35 includes a hole 53. It is formed for passing a separate fixing element, for example a screw.

In addition to the pre-assembly position for the wall unit 25 at the interior container 4 achievable by the positioning elements, in particular the plug pins 50 and/or 52, it is allowed by this hole 53 that the wall unit 25 can be correspondingly screwed to the interior container 4 for final assembly.

In this context, it is in particular additionally or instead possible that the engagement area 47 includes a hole 54, through which a fixing element separate therefrom such as in particular a screw can also be passed. Thereby, the wall unit 25 can additionally be screwed to the first wall 15. The wall unit 25 can be screwed to the second wall 19 through the hole 53.

In FIG. 4, seals 55 and 56 which are moreover exemplarily shown then abut on the wall areas 22 and 23 in the assembled state of the wall unit 25 to allow a sealing housing 20. The seals 55 and 56 are one piece seals. The seals 55, 56 are elastic. In one embodiment the seals 55, 56 are formed of rubber. Each seal 55, 56 is a bent and elongated seal 90. This means that the seal 55, 56 has the shape of a hose. The seal 55, 56 has a length axis B. The seal 55, 56 is not closed along the length axis B. This means that a first end 901 of the bent and elongated seal 90 and a second end 902 of the bent an elongated seal 90 are not in connection with each other.

The seals 55, 56 and therefore the bent an elongated seal 90 includes a hollow tube 91. The hollow tube 91 is hose-shaped. The hollow tube 91 has no gaps along the length axis B. In a plane perpendicular to the length axis B the hollow tube 91 has a circular cross section, or it may also have an oval cross section. In one embodiment, this occurs along the complete length of the hollow tube 91. Therefore in one embodiment the circular cross section is formed in a first seal section 90 a, in a second seal section 90 b (FIG. 24), in a third seal section 90 c (FIG. 24), and in a fourth seal section 90 d.

Further in one embodiment the circular or oval cross section is formed in a first seal section passage 90 e. This is a curved part of the bent and elongated seal 90. The first seal section passage 90 e connects the seal sections 90 a and 90 b. Further in one embodiment the circular or oval cross section is formed in a second seal section passage 90 f (FIG. 24). This is a curved part of the bent and elongated seal 90. The second seal section passage 90 f connects the seal sections 90 b and 90 c. Further in one embodiment the circular cross section is formed in a third seal section passage 90 g. This is a curved part of the bent and elongated seal 90. The third seal section passage 90 g connects the seal sections 90 c and 90 d.

As is shown in FIG. 4 and FIG. 24 the seal section passages 90 e, 90 f and 90 g connect the corresponding section sections 90 a, 90 b, 90 c, 90 d in such a way that these seal sections 90 a to 90 g are pairwise disposed at an angle between 80° and 100°, especially 85° and 95°.

As is shown the seal 55, 56 is disposed as a 3-dimensionally bent and elongated seal 90. This means that the seal sections 90 a to 90 d are not disposed linear to each other but in an angled orientation. These angled orientations are in different spatial directions. As can be seen in one embodiment the first seal section 90 a is orientated in the depth direction z. Along the length axis B the following second seal section 90 b is orientated in the height direction y. Along the length axis B the following third seal section 90 c is orientated in the width direction x. Along the length axis B the fourth seal section 90 d is orientated in the depth direction z.

The seal 55, 56 and therefore the bent and elongated seal 90 further includes a mounting strip 92. In one embodiment the mounting strip 92 has a bandlike shape. The mounting strip 92 and the hollow tube 91 are a one-piece part. The mounting strip 92 is a flat bar. The mounting strip 92 is without hollows. The mounting strip 92 is disposed on an outside of the hollow tube 91. The mounting strip 92 radially overhangs from the outside of the hollow tube 91. The mounting strip 92 is disposed like a wing on the outside of the hollow tube 91.

As can be seen in FIG. 4 the seal 55, 56 is disposed on an upper edge 28 a of the second wall plate 28. Further the seal 55, 56 is disposed on a second rear edge 28 b (FIG. 24) of the second wall plate 28. Further the seal 55, 56 is disposed on a side edge 27 a of the first wall plate 27. Further the seal 55, 56 is disposed on a second rear edge 27 b of the first wall plate 27.

The mounting strip 92 lies with the larger surface of its strip shape on the edges 27 a, 27 b, 28 a, 28 b.

At a first edge passage 28 c the mounting strip 92 lies flat on the first edge passage 28 c. Further a mounting strip edge 92 a of the mounting strip 92 is curved in the same way as the curvature of the first edge passage 28 c. Therefore, at this first edge passage 28 a no beading or folding of the mounting strip edge 92 a occurs. The mounting strip edge 92 a is the very small side of the mounting strip 92 in comparison to its two flat larger surfaces. The mounting strip edge 92 a defines the thickness of the mounting strip 92.

At a second edge passage 28 d (FIG. 24) the mounting strip edge 92 a would be beaded or folded. Therefore, at this position the mounting strip 92 includes a mounting strip gap 92 b (FIG. 24). This is a cutout in the mounting strip 92. Thus, no part of the mounting strip 92 is disposed at this second edge passage 28 d. Therefore, beading of the mounting strip edge 92 a at this position is avoided. The mounting strip gap 92 b is only in the area of the second edge passage 28 b.

At a third edge passage 27 c the mounting strip 92 has no gap. The mounting strip 92 lies flat on the third edge passage 27 c. Further the mounting strip edge 92 a of the mounting strip 92 is curved in the same way as the curvature of the third edge passage 27 c. Therefore, at this third edge passage 27 c no beading or folding of the mounting strip edge 92 a occurs.

As is shown in FIG. 4 and FIG. 24 the seal 55, 56 is mounted with holders 93 (FIGS. 4, 24, 25, 26, 27) on the wall plates 27 and 28. In one embodiment the holders 93 are spring clips. In one embodiment the mounting strip 92 includes holes 93 (FIG. 26, 27). The holders 94 extend through the holes 94. In one embodiment the holders 94 are snapped in snapping holes in the edges 27 a, 27 b, 28 a and 28 b.

The seal 55, 56 extends in all three spatial directions with its seal sections 90 a, 90 b, 90 c and 90 d when disposed on the housing 20. This means that the length axis B is orientated in these directions in these seal sections 90 a, 90 b, 90 c, 90 d.

With the seal 55, 56 disposed on the housing 20, sealing the housing 20 to the interior container 4 is achieved.

In one embodiment the bent and elongated seal 90 has the shape of an elongated leg. This means that the seal 90 is shaped like a cord or string.

In one embodiment the seal 55, 56 is formed of silicon.

The seal 55, 56 provides the advantage that a sealing function is achieved along the complete axis of the seal and therefore along the complete length of the seal 55, 56 without any interruption. Therefore, the sealing function is also achieved at the corners or curves of the bent and elongated seal 90. At the corners or curves and therefore at the bent sections of the bent an elongated seal 90 no reduction of the cross section of the seal 90 occurs. This is an advantage especially in a comparison foam seal.

In one embodiment the holders 94 are disposed at equal distances along the length axis B. Therefore, a sealing function is improved. Foam seals are glued to the walls. This is an advantage because this leads to thinner sections of the seal and leads to folds in the seal.

Further an advantage is a better and easier mounting of such a seal 55, 56. The seal 55, 56 includes the advantage that it absorbs no moisture.

In one embodiment the circular cross section of the hollow tube 91 at all length sections of the hollow tube 91 is advantageous for a better sealing function at the edges of the walls.

Further, the plug pins 50 and/or 52 in addition to the simple adjustment of a pre-assembly position of the wall unit 25, also allow centering of this wall unit 25 relative to the interior container 4. Non-destructively detachable positioning of the wall unit 25 at the interior container 4 is allowed by the plug pins 50 and 52. The pre-assembly position of the wall unit 25 at the interior container 4 is self-adherent. This means that an assembler no longer needs to retain the wall unit 25 himself or herself when he or she produces the screw connections to produce the assembled final position of the wall unit 25.

In FIG. 5, a partial area of the wall unit 25 according to the representation in FIG. 4 is shown, wherein a perspective different from FIG. 4 is presented in this case. In this case, the coupling flap 48 is apparent. In particular, the engagement area 47 is also shown, which is locked in the aperture 46.

In FIG. 6, the representation according to FIG. 5 is shown, wherein a horizontal sectional representation of the positioning bracket 32 in the second bracket leg 35 is illustrated therein. As is apparent in this context, the positioning bracket 32 includes an integrated, blind hole-like screw boss 57 in particular in the plate area 40. Thereby, the positioning bracket 32 can also be screwed to the wall plate 28.

In FIG. 7, the positioning bracket 32 is shown in a perspective representation.

In FIG. 8, the positioning bracket 32 is illustrated in a perspective different from FIG. 7. As is apparent in this case, the first bracket leg 34 includes retaining elements 58 and 59 protruding downwards at its end 36. These retaining elements 58 and 59 can be plug flaps or locking elements. Thereby, the positioning bracket 32 can additionally be non-destructively detachably attached to the wall element 26 in an improved manner.

In a further implementation, it is provided that the positioning bracket 32 includes at least one plug element 60, in this case preferably two separate and spaced-apart plug elements 60 and 61, at the second end 37. These plug elements 60, 61 are formed integrally with the positioning bracket 32. Upon assembly of the positioning bracket 32 to the wall element 26, these plug elements 60 and 61 are plugged into corresponding receptacles, one receptacle 62 of which is apparent in FIG. 6. This configuration too represents a fixing device, which is non-destructively detachable.

In FIG. 9, a partial area of the wall unit 25 is shown in a vertical sectional representation. In this case, the sectional line is drawn through the plug pin 52.

As is apparent, the plate area 40 includes a depression 63. The hole 53 is formed in this depression 63. The hole 53 is in particular formed as an elongated hole. Preferably, the hole 54 is also formed as an elongated hole.

As is apparent in FIG. 9, a washer 64 is introduced into this depression 63, through which a screw 65 is passed. Due to the configuration of the hole 53 as an elongated hole, a certain backlash and thus a tolerance for positional adjustment is in this case allowed since the washer 64 is disposed in the hole 53 with backlash.

In FIG. 9, a further washer 66 and a screw 67 are moreover shown. The washer 66 is in particular formed corresponding to the washer 64 and correspondingly plunges into the hole 54. In this case too, a certain positioning with backlash is thus allowed in such a way that a tolerance compensation is allowed. The wall unit 25 can be screwed to a screw boss 71, which is integrally formed in the wall area 22, by the screw 67 in such a way that a screw connection is formed at this place.

In FIG. 10, the partial section in FIG. 9 is shown in an enlarged representation, in which the screw 65 is illustrated. This backlash and thus this tolerance compensation are symbolized by the arrows in FIG. 10.

In FIG. 11, the assembled state of the wall unit 25 to the interior container 4 in this area of the positioning bracket 32 according to FIG. 10 is shown in a perspective sectional representation. In this case, it is apparent that the positioning element or the plug pin 52 plunges into a receptacle 68, which is formed integrally with the second wall 19, to allow the pre-assembly position and in particular also centering of the wall unit 25 around the interior container 4. The receptacle 68 is in particular formed as a blind hole. Moreover, a seal 69 is also shown in FIG. 11, which is disposed in the receiving groove 45.

In FIG. 12, it is shown in a perspective horizontal sectional representation, how the wall unit 25 is fixed to the first wall 15 in the area of the first end 36 of the positioning bracket 32.

In FIG. 13, a further embodiment for a wall unit 25 is shown in a perspective representation. In contrast to the representation according to FIG. 4, in this case it is provided that a locking element 70 is formed integrated and thus integrally on the wall plate 27 instead of the plug pin 50. In particular, the locking element 70 is disposed at the web 49. In particular, the locking element 70 is integrated in the inner wall element 30.

This locking element 70 can lock in a corresponding receptacle formed in the wall area 22. Moreover, in contrast to FIG. 4, the configuration of the positioning bracket 32, in particular of the second bracket leg 35, is slightly different from the configuration in FIG. 4. However, the basic and important functions and elements are provided in this case too. In particular, this relates to the positioning element in the form of the plug pin 52 as well as the plug elements 60, 61, the hole 53 and preferably also the screw boss 57.

In FIG. 14, the household refrigeration apparatus 1 is shown in the area of the ice maker 11 with the finally assembled housing 20 in an enlarged representation. The wall unit 25 is represented in its end position at the interior container 4 in this context.

As is also apparent in FIG. 14, the front edge 38 is non-destructively detachably connected, in particular locked, to the outer wall element 29. Two locking elements 72 and 73 are exemplarily apparent therein.

Further, it is provided that in one embodiment, which can be provided independently of the previous explanations with regard to the configuration of the wall unit 25, a wall step 74 is formed at the first wall 15 and in the wall area 22, which bounds the receiving space 21 of the ice maker 11 and is associated with the housing 20.

In FIG. 15, the housing 20 is shown in a vertical sectional representation, wherein the wall step 74 is also apparent in this case.

The wall step 74 includes a protrusion 75. The protrusion 75 protrudes into the receiving space 21 of the ice maker 11 as viewed in the width direction of the household refrigeration apparatus 1. This protrusion 75 is formed as a condensation water drip bar 76.

A recess 77 is formed below the protrusion 75 in the height direction. The wall element 26 plunges into this recess 77 as viewed in width direction. In particular, this plunging is provided in such a way that the web 49 is completely disposed in this recess 77. In particular, the protrusion 75 further protrudes into the receiving space 21 than the groove 49 is wide in this width direction. Thereby, the dripping of condensation water from the condensation water drip bar 76 is allowed in such a way that water cannot get laterally past the groove 49 and thus into the recess 77. The condensation water drips from the condensation water drip bar 76 directly onto that area of the inner wall element 30, which inwardly adjoins to the web 49.

In FIG. 16, an enlarged representation of the view in FIG. 15 is shown, wherein that section in the area of the protrusion 75 and the recess 77 is shown therein. Preferably, it is provided that an angle α, which is measured between a protrusion wall 79 of the protrusion 75 and the downward adjoining wall section 78 of the first wall 15 or the wall area 22, is less than or equal to 110°, in particular less than or equal to 90°.

In FIG. 17, a partial section of the interior container 4 with view to the rear wall 17 is shown. In this case, a viewing direction into the receiving space 6 is illustrated. In the wall area 24 of the rear wall 17, a drain gutter 80 is shown formed integrally therewith. Condensation water, which occurs in the ice maker 11, can in particular be conducted to this drain gutter 80 by the first wall plate 27. Therefore, the inner wall element 30 of the wall element 26 is preferably obliquely rearward inclined in particular in the area of the first wall plate 27. In this context, condensation water, which drips to the top side of the inner wall element 30 through the condensation water drip bar 76, can in particular be conducted to the rear in a defined and targeted manner and thus then enters into the drain gutter 80.

The drain gutter 80 includes a drain stub 81. A drain line 95, as it is shown in FIGS. 21 and 22, can be connected to the drain stub 81.

The drain gutter 80 includes a front gutter edge 82 as viewed in the depth direction. This front gutter edge 82 can also serve as a rest for a web of the first wall plate 27.

In addition or instead, it can be provided that a pedestal base 83 formed spaced from and independently of the front gutter edge 82 is integrally formed in the interior container 4. This pedestal base 83 can serve as a rest for the first horizontal wall plate 27. As is moreover apparent in FIG. 17, the rear wall 17 includes two screw domes 84 and 85 in this embodiment. The screw domes 84 and 85 are formed integrally with the rear wall 17. They are preferably formed in the area of the pedestal base 83. The wall element 26 can be screwed to the rear wall 19 by these screw domes 84 and 85.

In FIG. 18, the interior container 4 is shown in its upper area, wherein a view to the rear wall 17 from behind is provided in this case. Thus, a view is directed from the foam side to the rear wall 17, which means that it is looked from the clearance 5 towards the rear wall 17.

In this case, it is apparent that a pedestal 86 is integrally formed at the rear wall 17 in an advantageous implementation. This pedestal 86 is formed offset rearward with respect to a base plate 87 of the rear wall 17 as viewed in the depth direction. Thus, the pedestal 86 is formed backpack-like at the base plate 87. As is apparent in FIG. 18, the drain gutter 80 is formed at the lower end of the pedestal 86, in particular formed completely within the pedestal 86. The drain gutter 80 is therefore disposed offset rearward with respect to the base plate 87 as viewed in the depth direction. In particular, the drain gutter 80 is thus virtually rearward offset from the volume, which is bounded by the base plate 87, and thus rearward offset towards the clearance 5. Thus, the drain gutter 80 is displaced into the area, in which the insulating foam is disposed.

Moreover, it is also apparent in FIG. 18 that the drain gutter 80 bulges out rearward with respect to the pedestal 86, which is formed with a trough-like shape, and thus forms a bead-like protrusion towards the bottom and the rear. Preferably, the drain gutter 80 extends across the entire width of the pedestal 86.

In FIG. 19, the interior container 4 is shown in a transparent side view in an implementation. The above-mentioned positional configurations of the drain gutter 80 to the base plate 87 are apparent. Moreover, it is also apparent that the protrusion 75 extends uninterrupted from the front end of the housing 20 up to the drain gutter 80.

In FIG. 20, a partial area of the interior container 4 is shown in an enlarged representation, as illustrated in FIG. 19. In this case, that partial area with the pedestal 86 and the drain gutter 80 is in particular again clarified.

In FIG. 21, the interior container 4 is shown in the upper area in a sectional representation, wherein the wall unit 25 is also shown therein in the assembled final state and is apparent in a vertical sectional representation.

In FIG. 22, the rear area with the drain gutter 80 is shown in an enlarged representation. As is apparent, the first wall plate 27 includes a web 88 protruding rearward as viewed in the depth direction. This rearward protruding protrusion in the form of the web 88 extends up into the drain gutter 80. In particular, this web 88 is disposed upward offset and contactless to the front gutter edge 82, as is shown in FIG. 22. The web 88 extends in the depth direction for example as far as it completely covers the front gutter edge 82.

Thereby, it is also allowed that the drain of the condensation water from the first wall plate 27 is securely effected into the drain gutter 80 on the one hand. On the other hand and independently thereof, it is thereby then also allowed that the first wall plate 27 is positionally securely and mechanically stably retained and virtually rests on this front gutter edge 82. Thereby, it is in particular also allowed that a pre-assembly position of the wall unit 25 is now also securely achieved at this location in addition to the previously mentioned examples with the positioning elements or instead thereof.

In addition or instead, it can be provided that the first wall plate 27 rests on the pedestal base 83, as shown in FIG. 22. The screw joint or a screw connection, in particular of the first wall plate 27 to the screw boss 84, is also shown, wherein a screw 89 is illustrated herein. In FIG. 22, a state is shown, in which the web 88 protrudes into the drain gutter 80 as viewed in the depth direction, but is disposed spaced from the front gutter edge 82 at this location.

In FIG. 23, in a perspective sectional representation, which is slightly offset to the right in the width direction with respect to the representation in FIG. 22, a corresponding area is shown as is represented in FIG. 22.

Further, in this embodiment, but which is not to be conclusively understood, four screw connections are provided, by which the wall unit 25 is fixed to the interior container 4. This relates to the screw connection with the screw 67, the screw connection with the screw 65 and the screw connections with screws 89 at the screw domes 84 and 85. More or less screw connections can also be provided.

In a method for assembling the housing 20 of the ice maker 11, the interior container 4 is produced and provided integrally with the first wall 15 and with the second wall 19 disposed angled thereto. Furthermore, a wall unit 25 separate from the interior container 4 is provided, wherein the wall unit 25 includes at least one positioning element, which is formed integrally with the wall unit 25. The positioning elements are produced as plug pins 50 and/or 52 and/or as a locking element 70. This wall unit 25 is introduced into the receiving space 6 of the interior container 4. In particular, the web 88 is first placed on the pedestal base 83. At the same time or subsequently, the plug pin 50 is introduced into the receptacle 51 and/or the plug pin 52 is introduced into the receptacle 68 in this embodiment. Since the plug pins 50 and 52 are oriented in different spatial directions, namely in width direction and in height direction, a pre-assembly position in height direction and in width direction, in particular in the front area 33, can be autonomously retained by this implementation. The same is achieved with the locking element 70 if it is provided instead of the plug pin 50. The plug pin 52 can for example also be replaced with a locking element. The pre-assembly position is securely and autonomously retained there too by the rest of the web 88 on the pedestal base 83 in the rear area of the housing 20.

As already explained above in FIG. 24 a perspective view of an enlarged representation of a partial area of the housing 20 of the ice maker of the household refrigeration apparatus 1 with a disposed seal 55, 56 is shown. The perspective view is different than FIG. 4 and FIG. 13.

In FIG. 25 the 3-dimensionally bent seal 55, 56 from FIG. 24 is shown. Further the holders 94 are shown.

In FIG. 26 the seal 55, 56 shown in FIG. 25 is shown in an unbent state. Therefore, the seal 55, 56 is shown in a complete linear state. The mounting strip gap 92 b is shown.

Further in FIG. 27 an enlarged end 901 of the seal 55, 56 in FIG. 26 is shown, especially with a holder 94.

In this pre-assembly position, the subsequent screwing of the screws, which are provided for producing the screw connections, and by which the final position of the wall unit 25 at the interior container 4 is produced, can be effected without an assembler having to retain the wall unit 25. The assembler then has both hands free to produce the screw connections.

In one embodiment the seal includes a hollow tube.

In one embodiment the seal includes a mounting strip.

In one embodiment the mounting strip is without hollows.

In one embodiment the seal includes a length axis and the hollow tube includes no gap along the length axis.

In one embodiment the seal includes a length axis and in a plane perpendicular to the length axis the hollow tube includes a circular cross section.

In one embodiment the mounting strip is disposed on the outside of the hollow tube.

In one embodiment the mounting strip overhangs from the outside of the hollow tube.

In one embodiment the mounting strip includes a mounting strip gap.

In one embodiment the mounting strip includes holes and the ice maker includes separate holders disposed in the holes fixing the seal at the housing.

In one embodiment the holders are spring clips.

In one embodiment the seal leg disposed on the housing extends in all three spatial directions.

In one embodiment the seal is elastic.

In one embodiment the first wall plate includes a side edge and a rear edge and the seal is disposed on the side edge and the rear edge.

In one embodiment the second wall plate includes an upper edge and a rear edge and the seal is disposed on the upper edge and the rear edge.

In one embodiment the wall element has an L-shape in cross-section, and the first wall plate and the second wall plate together form the L-shape.

In one embodiment the first wall plate and the second wall plate are a one-piece plate.

Individual advantageous developments of an ice maker, in particular the housing of the ice maker, of the household refrigeration apparatus can be provided generally and independently of the explained embodiments.

In one embodiment, the positioning bracket has an L-shape.

Preferably, the positioning bracket is integrally formed. Preferably, the housing has a depth direction, and the wall element includes a front area viewed in depth direction, wherein the positioning bracket is disposed on the front area.

In one embodiment, the front area includes a front edge, and a circumferentially closed frame is formed by the front edge and the positioning bracket.

In one embodiment, the positioning bracket includes a bracket leg and at least one stiffening rib is formed at the bracket leg.

In one embodiment, the stiffening rib is oriented in the direction of a longitudinal axis of the positioning bracket and is a bounding wall of a receiving groove for a seal.

In one embodiment, the positioning bracket includes a bracket leg, at the end of which at least one locking element is integrally formed.

In one embodiment, the household refrigeration apparatus includes an interior container, which bounds a first receiving space for food of the household refrigeration apparatus, and the positioning bracket includes at least one positioning element for non-destructively detachably pre-positioning the housing at the interior container.

In one embodiment, the positioning bracket includes a bracket leg, at the end of which at least one plug element is integrally formed.

In one embodiment, the positioning bracket includes a bracket leg, which includes a plate area, wherein a depression for receiving a washer is formed in the plate area, and a hole for passing a fixing element is formed in the depression.

In one embodiment, the positioning bracket includes a bracket leg, which includes an aperture, and the wall element includes a coupling flap for coupling to the positioning bracket, wherein the coupling flap includes an engagement area, which engages with the aperture.

In one embodiment, the engagement area includes a hole for passing a fixing element.

In one embodiment, the positioning bracket includes a bracket leg, and the bracket leg includes an integrated, blind hole-like screw boss.

In one embodiment, the housing has a depth direction, and the wall unit includes a front area viewed in the depth direction, wherein the plug pin or the locking element is disposed on the front area.

In one embodiment, the wall unit includes a wall element, which has an L-shape in cross-section, wherein the wall element includes a first wall plate and a second wall plate, which together form the L-shape, wherein a plug pin or a locking element is disposed at an edge of the first wall plate.

In one embodiment, the wall unit includes a non-rectilinear positioning bracket, which includes a horizontal bracket leg, and a plug pin is disposed on a top side of the horizontal bracket leg.

In one embodiment, the positioning bracket has an L-shape, which is formed by the horizontal bracket leg and a vertical bracket leg.

In one embodiment, the positioning bracket is integrally formed and is a component separate from the wall element, wherein the positioning bracket is non-destructively detachably connected to the wall element.

In one embodiment, the wall area of the first wall or the wall area of the second wall includes a receptacle, to which the plug pin or the locking element can be non-destructively detachably attached for forming a pre-assembly position of the wall unit at the interior container.

In one embodiment, the wall unit is disposed at the interior container with at least one screw connection in addition to the at least one plug pin or the at least one locking element.

In one embodiment, the interior container includes a rear wall, and the rear wall includes a step, which is a rest, on which the wall unit rests.

In one embodiment, the wall unit includes a wall element, which is a component separate from the interior container, the wall element has an L-shape in cross-section, and the wall element includes a first wall plate and a second wall plate, which together form the L-shape, the household refrigeration apparatus has a depth direction, and the first wall plate includes a rear web protruding rearward in the depth direction and the web rests on the step.

In one embodiment, the household refrigeration apparatus has a depth direction and the interior container includes a rear wall with a base plate, in which a drain gutter for condensation water, which forms in the ice maker, is integrally formed, wherein the drain gutter is disposed offset rearward compared to the base plate of the rear wall as viewed in the depth direction.

In one embodiment, the drain gutter includes a front gutter edge and the web is disposed above the front gutter edge in a contactless manner and the web extends across the entire thickness, which is measured in the depth direction, of the front groove gutter edge as viewed in the depth direction.

In one embodiment, the household refrigeration apparatus has a depth direction, and the interior container includes a rear wall with a base plate, and a drain gutter for condensation water, which forms in the ice maker, is formed integrally in the rear wall. The rear wall includes a pedestal, which is formed integrally with the base plate and which is disposed offset rearward compared to the base plate in the depth direction, the drain gutter is formed in the pedestal, the pedestal includes a lower pedestal base spaced from the drain gutter, which forms the step, and the web rests on the pedestal base.

In one embodiment, the protrusion includes a protrusion wall, and an angle between the protrusion wall and a further wall section of the first wall downwards adjoining to the protrusion is less than or equal to 110°, in particular less than or equal to 90°.

In one embodiment, the household refrigeration apparatus has a depth direction, and the protrusion extends across the entire length of the housing of the ice maker in this depth direction.

In one embodiment, the housing of the ice maker includes a wall element, which is a component separate from the interior container, the wall element has an L-shape in cross-section, and the wall element includes a first wall plate and a second wall plate, which together form the L-shape, the household refrigeration apparatus has a height direction, and a recess is formed below the protrusion in the height direction, into which the wall element extends.

In one embodiment, an inner wall of the first wall plate is rearwardly inclined at least in certain areas as viewed in the depth direction.

In one embodiment, the household refrigeration apparatus has a depth direction and the interior container includes a rear wall with a base plate, in which a drain gutter for condensation water, which forms in the ice maker, is integrally formed, wherein the drain gutter is disposed offset rearward compared to the base plate as viewed in the depth direction.

In one embodiment, the rear wall includes a pedestal, which is formed integrally with the base plate and which is disposed offset rearward compared to the base plate in depth direction, and the drain gutter is formed in the pedestal and bulges out rearward with respect to a rear end wall of the pedestal.

In one embodiment, the pedestal is a wall area of the housing of the ice maker, by which a receiving space of the ice maker is bounded.

In one embodiment, the drain gutter includes an integrated drain stub.

In one embodiment, the housing of the ice maker includes a wall element, which is a component separate from the interior container, the wall element has an L-shape in cross-section and the wall element includes a first wall plate and a second wall plate, which together form the L-shape, the household refrigeration apparatus has a depth direction, and the first wall plate includes a rear web, wherein the web protrudes into the drain gutter as viewed in the depth direction.

In one embodiment, the drain gutter includes a front gutter edge and the web is disposed contactless to the front gutter edge above the front gutter edge. As viewed in the depth direction, the web extends across the entire thickness, which is measured in the depth direction, of the front gutter edge.

LIST OF REFERENCE CHARACTERS

-   1 Household refrigeration apparatus -   2 housing -   3 exterior housing -   4 interior container -   5 clearance -   6 receiving space -   7 door -   8 door -   9 receiving space -   10 door -   11 ice maker -   12 dispenser unit -   13 output unit -   14 front side -   15 side wall -   16 side wall -   17 rear wall -   18 bottom wall -   19 ceiling wall -   20 housing -   21 receiving space -   22 wall area -   23 wall area -   24 wall area -   25 wall unit -   26 wall element -   27 wall plate -   27 a side edge -   27 b first rear edge -   27 c third edge passage -   28 wall plate -   28 a upper edge -   28 b second rear edge -   28 c first edge passage -   28 d second edge passage -   29 outer wall element -   30 inner wall element -   31 thermally insulating material -   32 positioning bracket -   33 front area -   34 bracket leg -   35 bracket leg -   36 first end -   37 second end -   38 front edge -   39 stiffening rib -   40 plate area -   41 bounding wall -   42 stiffening rib -   43 outer side -   44 stiffening rib -   45 receiving groove -   46 aperture -   47 engagement area -   48 coupling flap -   49 web -   50 plug pin -   51 receptacle -   52 positioning element -   53 hole -   54 hole -   55 seal -   56 seal -   57 screw boss -   58 retaining element -   59 retaining element -   60 plug element -   61 plug element -   62 receptacle -   63 depression -   64 washer -   65 screw -   66 washer -   67 screw -   68 receptacle -   69 seal -   70 locking element -   71 screw boss -   72 locking element -   73 locking element -   74 wall step -   75 protrusion -   76 condensation water drip bar -   77 recess -   78 wall section -   79 protrusion wall -   80 drain gutter -   81 drain stub -   82 gutter edge -   83 pedestal base -   84 screw boss -   85 screw boss -   86 pedestal -   87 base plate -   88 web -   89 screw -   90 bent and elongated seal -   90 a first seal section -   90 b second seal section -   90 c third seal section -   90 d fourth seal section -   90 e first seal section passage -   90 f second seal section passage -   90 g third seal section passage -   91 hollow tube -   92 mounting strip -   92 a mounting strip edge -   92 b mounting strip gap -   93 hole -   94 holder -   95 drain line -   901 end -   902 end -   A angle -   B length axis 

1. An ice maker, comprising: a housing including a wall element; said wall element including a first wall plate and a second wall plate; and a seal disposed on said housing and sealing said housing to an interior container of a household refrigeration apparatus; said seal including a hollow tube and said seal being a 3-dimensionally bent and elongated seal.
 2. The ice maker according to claim 1, wherein said seal is a one-piece seal.
 3. The ice maker according to claim 2, wherein said seal includes a mounting strip.
 4. The ice maker according to claim 3, wherein said mounting strip is without hollows.
 5. The ice maker according to claim 2, wherein said seal has a length axis, and said hollow tube has no gap along said length axis.
 6. The ice maker according to claim 3, wherein said seal has a length axis, and said hollow tube has a circular cross or an oval section in a plane perpendicular to said length axis.
 7. The ice maker according to claim 3, wherein said mounting strip is disposed on an outside of said hollow tube.
 8. The ice maker according to claim 7, wherein said mounting strip overhangs from said outside of said hollow tube.
 9. The ice maker according to claim 3, wherein said mounting strip has a mounting strip gap.
 10. The ice maker according to claim 3, wherein said mounting strip has holes and, separate holders of the ice maker are disposed in said holes and fix said seal at said housing.
 11. The ice maker according to claim 10, wherein said holders are spring clips.
 12. The ice maker according to claim 1, wherein said 3-dimensionally bent and elongated seal disposed on said housing extends in all three spatial directions.
 13. The ice maker according to claim 1, wherein said seal is elastic.
 14. The ice maker according to claim 1, wherein said first wall plate includes a side edge and a first rear edge, and said seal is disposed on said side edge and said first rear edge and extends along a third edge passage between said side edge and said first rear edge.
 15. The ice maker according to claim 1, wherein said second wall plate includes an upper edge and a second rear edge, and said seal is disposed on said upper edge and said second rear edge and extends along a first edge passage between said upper edge and said second rear edge.
 16. The ice maker according to claim 1, wherein said first wall plate includes a first rear edge, said second wall plate includes a second rear edge, and said seal is disposed on said first rear edge and said second rear edge and extends along a second edge passage between the said first rear edge and said second rear edge.
 17. The ice maker according to claim 1, wherein said wall element has an L-shape in cross-section, and said first wall plate and said second wall plate together form said L-shape.
 18. The ice maker according to claim 17, wherein said first wall plate and said second wall plate are formed as a one piece plate.
 19. A household refrigeration apparatus, comprising: an interior container; and an ice maker including: a housing disposed on said interior container; said housing including a wall element having a first wall plate and a second wall plate; and a seal disposed on said housing and sealing said housing to said interior container; said seal including a hollow tube and being a 3-dimensionally bent and elongated seal. 